discovery.rs
695 lines
| 22.8 KiB
| application/rls-services+xml
|
RustLexer
Georges Racinet
|
r42355 | // discovery.rs | ||
// | ||||
// Copyright 2019 Georges Racinet <georges.racinet@octobus.net> | ||||
// | ||||
// This software may be used and distributed according to the terms of the | ||||
// GNU General Public License version 2 or any later version. | ||||
//! Discovery operations | ||||
//! | ||||
//! This is a Rust counterpart to the `partialdiscovery` class of | ||||
//! `mercurial.setdiscovery` | ||||
Georges Racinet
|
r42965 | use super::{Graph, GraphError, Revision, NULL_REVISION}; | ||
Georges Racinet
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r42355 | use crate::ancestors::MissingAncestors; | ||
use crate::dagops; | ||||
Yuya Nishihara
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r43031 | use rand::seq::SliceRandom; | ||
use rand::{thread_rng, RngCore, SeedableRng}; | ||||
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r42966 | use std::cmp::{max, min}; | ||
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r42965 | use std::collections::{HashMap, HashSet, VecDeque}; | ||
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r43031 | type Rng = rand_pcg::Pcg32; | ||
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r42355 | |||
pub struct PartialDiscovery<G: Graph + Clone> { | ||||
target_heads: Option<Vec<Revision>>, | ||||
graph: G, // plays the role of self._repo | ||||
common: MissingAncestors<G>, | ||||
undecided: Option<HashSet<Revision>>, | ||||
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r42966 | children_cache: Option<HashMap<Revision, Vec<Revision>>>, | ||
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r42355 | missing: HashSet<Revision>, | ||
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r42965 | rng: Rng, | ||
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r42966 | respect_size: bool, | ||
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r42968 | randomize: bool, | ||
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r42355 | } | ||
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r42357 | pub struct DiscoveryStats { | ||
pub undecided: Option<usize>, | ||||
} | ||||
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r42965 | /// Update an existing sample to match the expected size | ||
/// | ||||
/// The sample is updated with revisions exponentially distant from each | ||||
/// element of `heads`. | ||||
/// | ||||
/// If a target size is specified, the sampling will stop once this size is | ||||
/// reached. Otherwise sampling will happen until roots of the <revs> set are | ||||
/// reached. | ||||
/// | ||||
/// - `revs`: set of revs we want to discover (if None, `assume` the whole dag | ||||
/// represented by `parentfn` | ||||
/// - `heads`: set of DAG head revs | ||||
/// - `sample`: a sample to update | ||||
/// - `parentfn`: a callable to resolve parents for a revision | ||||
/// - `quicksamplesize`: optional target size of the sample | ||||
Georges Racinet
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r42966 | fn update_sample<I>( | ||
Georges Racinet
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r42965 | revs: Option<&HashSet<Revision>>, | ||
heads: impl IntoIterator<Item = Revision>, | ||||
sample: &mut HashSet<Revision>, | ||||
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r42966 | parentsfn: impl Fn(Revision) -> Result<I, GraphError>, | ||
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r42965 | quicksamplesize: Option<usize>, | ||
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r42966 | ) -> Result<(), GraphError> | ||
where | ||||
I: Iterator<Item = Revision>, | ||||
{ | ||||
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r42965 | let mut distances: HashMap<Revision, u32> = HashMap::new(); | ||
let mut visit: VecDeque<Revision> = heads.into_iter().collect(); | ||||
let mut factor: u32 = 1; | ||||
let mut seen: HashSet<Revision> = HashSet::new(); | ||||
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r43032 | while let Some(current) = visit.pop_front() { | ||
Georges Racinet
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r42965 | if !seen.insert(current) { | ||
continue; | ||||
} | ||||
let d = *distances.entry(current).or_insert(1); | ||||
if d > factor { | ||||
factor *= 2; | ||||
} | ||||
if d == factor { | ||||
sample.insert(current); | ||||
if let Some(sz) = quicksamplesize { | ||||
if sample.len() >= sz { | ||||
return Ok(()); | ||||
} | ||||
} | ||||
} | ||||
Georges Racinet
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r42966 | for p in parentsfn(current)? { | ||
Georges Racinet
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r42965 | if let Some(revs) = revs { | ||
if !revs.contains(&p) { | ||||
continue; | ||||
} | ||||
} | ||||
distances.entry(p).or_insert(d + 1); | ||||
visit.push_back(p); | ||||
} | ||||
} | ||||
Ok(()) | ||||
} | ||||
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r42966 | struct ParentsIterator { | ||
parents: [Revision; 2], | ||||
cur: usize, | ||||
} | ||||
impl ParentsIterator { | ||||
fn graph_parents( | ||||
graph: &impl Graph, | ||||
r: Revision, | ||||
) -> Result<ParentsIterator, GraphError> { | ||||
Ok(ParentsIterator { | ||||
parents: graph.parents(r)?, | ||||
cur: 0, | ||||
}) | ||||
} | ||||
} | ||||
impl Iterator for ParentsIterator { | ||||
type Item = Revision; | ||||
fn next(&mut self) -> Option<Revision> { | ||||
if self.cur > 1 { | ||||
return None; | ||||
} | ||||
let rev = self.parents[self.cur]; | ||||
self.cur += 1; | ||||
if rev == NULL_REVISION { | ||||
return self.next(); | ||||
} | ||||
Some(rev) | ||||
} | ||||
} | ||||
Georges Racinet
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r42355 | impl<G: Graph + Clone> PartialDiscovery<G> { | ||
/// Create a PartialDiscovery object, with the intent | ||||
/// of comparing our `::<target_heads>` revset to the contents of another | ||||
/// repo. | ||||
/// | ||||
/// For now `target_heads` is passed as a vector, and will be used | ||||
/// at the first call to `ensure_undecided()`. | ||||
/// | ||||
/// If we want to make the signature more flexible, | ||||
/// we'll have to make it a type argument of `PartialDiscovery` or a trait | ||||
/// object since we'll keep it in the meanwhile | ||||
Georges Racinet
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r42966 | /// | ||
/// The `respect_size` boolean controls how the sampling methods | ||||
/// will interpret the size argument requested by the caller. If it's | ||||
/// `false`, they are allowed to produce a sample whose size is more | ||||
/// appropriate to the situation (typically bigger). | ||||
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r42968 | /// | ||
/// The `randomize` boolean affects sampling, and specifically how | ||||
/// limiting or last-minute expanding is been done: | ||||
/// | ||||
/// If `true`, both will perform random picking from `self.undecided`. | ||||
/// This is currently the best for actual discoveries. | ||||
/// | ||||
/// If `false`, a reproductible picking strategy is performed. This is | ||||
/// useful for integration tests. | ||||
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r42966 | pub fn new( | ||
graph: G, | ||||
target_heads: Vec<Revision>, | ||||
respect_size: bool, | ||||
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r42968 | randomize: bool, | ||
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r42966 | ) -> Self { | ||
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r42965 | let mut seed: [u8; 16] = [0; 16]; | ||
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r42968 | if randomize { | ||
thread_rng().fill_bytes(&mut seed); | ||||
} | ||||
Self::new_with_seed(graph, target_heads, seed, respect_size, randomize) | ||||
Georges Racinet
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r42965 | } | ||
pub fn new_with_seed( | ||||
graph: G, | ||||
target_heads: Vec<Revision>, | ||||
seed: [u8; 16], | ||||
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r42966 | respect_size: bool, | ||
Georges Racinet
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r42968 | randomize: bool, | ||
Georges Racinet
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r42965 | ) -> Self { | ||
Georges Racinet
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r42355 | PartialDiscovery { | ||
undecided: None, | ||||
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r42966 | children_cache: None, | ||
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r42355 | target_heads: Some(target_heads), | ||
graph: graph.clone(), | ||||
common: MissingAncestors::new(graph, vec![]), | ||||
missing: HashSet::new(), | ||||
Georges Racinet
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r42965 | rng: Rng::from_seed(seed), | ||
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r42966 | respect_size: respect_size, | ||
Georges Racinet
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r42968 | randomize: randomize, | ||
Georges Racinet
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r42355 | } | ||
} | ||||
Georges Racinet
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r42965 | /// Extract at most `size` random elements from sample and return them | ||
/// as a vector | ||||
fn limit_sample( | ||||
&mut self, | ||||
mut sample: Vec<Revision>, | ||||
size: usize, | ||||
) -> Vec<Revision> { | ||||
Georges Racinet
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r42968 | if !self.randomize { | ||
sample.sort(); | ||||
sample.truncate(size); | ||||
return sample; | ||||
} | ||||
Georges Racinet
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r42965 | let sample_len = sample.len(); | ||
if sample_len <= size { | ||||
return sample; | ||||
} | ||||
let rng = &mut self.rng; | ||||
let dropped_size = sample_len - size; | ||||
let limited_slice = if size < dropped_size { | ||||
sample.partial_shuffle(rng, size).0 | ||||
} else { | ||||
sample.partial_shuffle(rng, dropped_size).1 | ||||
}; | ||||
limited_slice.to_owned() | ||||
} | ||||
Georges Racinet
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r42355 | /// Register revisions known as being common | ||
pub fn add_common_revisions( | ||||
&mut self, | ||||
common: impl IntoIterator<Item = Revision>, | ||||
) -> Result<(), GraphError> { | ||||
Georges Racinet on percheron.racinet.fr
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r42971 | let before_len = self.common.get_bases().len(); | ||
Georges Racinet
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r42355 | self.common.add_bases(common); | ||
Georges Racinet on percheron.racinet.fr
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r42971 | if self.common.get_bases().len() == before_len { | ||
return Ok(()); | ||||
} | ||||
Georges Racinet
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r42355 | if let Some(ref mut undecided) = self.undecided { | ||
self.common.remove_ancestors_from(undecided)?; | ||||
} | ||||
Ok(()) | ||||
} | ||||
/// Register revisions known as being missing | ||||
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r42970 | /// | ||
/// # Performance note | ||||
/// | ||||
/// Except in the most trivial case, the first call of this method has | ||||
/// the side effect of computing `self.undecided` set for the first time, | ||||
/// and the related caches it might need for efficiency of its internal | ||||
/// computation. This is typically faster if more information is | ||||
/// available in `self.common`. Therefore, for good performance, the | ||||
/// caller should avoid calling this too early. | ||||
Georges Racinet
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r42355 | pub fn add_missing_revisions( | ||
&mut self, | ||||
missing: impl IntoIterator<Item = Revision>, | ||||
) -> Result<(), GraphError> { | ||||
Georges Racinet on percheron.racinet.fr
|
r42971 | let mut tovisit: VecDeque<Revision> = missing.into_iter().collect(); | ||
if tovisit.is_empty() { | ||||
return Ok(()); | ||||
} | ||||
Georges Racinet
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r42970 | self.ensure_children_cache()?; | ||
self.ensure_undecided()?; // for safety of possible future refactors | ||||
let children = self.children_cache.as_ref().unwrap(); | ||||
let mut seen: HashSet<Revision> = HashSet::new(); | ||||
Georges Racinet
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r42355 | let undecided_mut = self.undecided.as_mut().unwrap(); | ||
Georges Racinet
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r42970 | while let Some(rev) = tovisit.pop_front() { | ||
if !self.missing.insert(rev) { | ||||
// either it's known to be missing from a previous | ||||
// invocation, and there's no need to iterate on its | ||||
// children (we now they are all missing) | ||||
// or it's from a previous iteration of this loop | ||||
// and its children have already been queued | ||||
continue; | ||||
} | ||||
undecided_mut.remove(&rev); | ||||
match children.get(&rev) { | ||||
None => { | ||||
continue; | ||||
} | ||||
Some(this_children) => { | ||||
for child in this_children.iter().cloned() { | ||||
if seen.insert(child) { | ||||
tovisit.push_back(child); | ||||
} | ||||
} | ||||
} | ||||
} | ||||
Georges Racinet
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r42355 | } | ||
Ok(()) | ||||
} | ||||
/// Do we have any information about the peer? | ||||
pub fn has_info(&self) -> bool { | ||||
self.common.has_bases() | ||||
} | ||||
/// Did we acquire full knowledge of our Revisions that the peer has? | ||||
pub fn is_complete(&self) -> bool { | ||||
self.undecided.as_ref().map_or(false, |s| s.is_empty()) | ||||
} | ||||
/// Return the heads of the currently known common set of revisions. | ||||
/// | ||||
/// If the discovery process is not complete (see `is_complete()`), the | ||||
/// caller must be aware that this is an intermediate state. | ||||
/// | ||||
/// On the other hand, if it is complete, then this is currently | ||||
/// the only way to retrieve the end results of the discovery process. | ||||
/// | ||||
/// We may introduce in the future an `into_common_heads` call that | ||||
/// would be more appropriate for normal Rust callers, dropping `self` | ||||
/// if it is complete. | ||||
pub fn common_heads(&self) -> Result<HashSet<Revision>, GraphError> { | ||||
self.common.bases_heads() | ||||
} | ||||
/// Force first computation of `self.undecided` | ||||
/// | ||||
/// After this, `self.undecided.as_ref()` and `.as_mut()` can be | ||||
/// unwrapped to get workable immutable or mutable references without | ||||
/// any panic. | ||||
/// | ||||
/// This is an imperative call instead of an access with added lazyness | ||||
/// to reduce easily the scope of mutable borrow for the caller, | ||||
/// compared to undecided(&'a mut self) -> &'a… that would keep it | ||||
/// as long as the resulting immutable one. | ||||
fn ensure_undecided(&mut self) -> Result<(), GraphError> { | ||||
if self.undecided.is_some() { | ||||
return Ok(()); | ||||
} | ||||
let tgt = self.target_heads.take().unwrap(); | ||||
self.undecided = | ||||
Some(self.common.missing_ancestors(tgt)?.into_iter().collect()); | ||||
Ok(()) | ||||
} | ||||
Georges Racinet
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r42357 | |||
Georges Racinet
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r42966 | fn ensure_children_cache(&mut self) -> Result<(), GraphError> { | ||
if self.children_cache.is_some() { | ||||
return Ok(()); | ||||
} | ||||
self.ensure_undecided()?; | ||||
let mut children: HashMap<Revision, Vec<Revision>> = HashMap::new(); | ||||
for &rev in self.undecided.as_ref().unwrap() { | ||||
for p in ParentsIterator::graph_parents(&self.graph, rev)? { | ||||
children.entry(p).or_insert_with(|| Vec::new()).push(rev); | ||||
} | ||||
} | ||||
self.children_cache = Some(children); | ||||
Ok(()) | ||||
} | ||||
Georges Racinet
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r42357 | /// Provide statistics about the current state of the discovery process | ||
pub fn stats(&self) -> DiscoveryStats { | ||||
DiscoveryStats { | ||||
undecided: self.undecided.as_ref().map(|s| s.len()), | ||||
} | ||||
} | ||||
Georges Racinet
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r42965 | |||
pub fn take_quick_sample( | ||||
&mut self, | ||||
headrevs: impl IntoIterator<Item = Revision>, | ||||
size: usize, | ||||
) -> Result<Vec<Revision>, GraphError> { | ||||
self.ensure_undecided()?; | ||||
let mut sample = { | ||||
let undecided = self.undecided.as_ref().unwrap(); | ||||
if undecided.len() <= size { | ||||
return Ok(undecided.iter().cloned().collect()); | ||||
} | ||||
dagops::heads(&self.graph, undecided.iter())? | ||||
}; | ||||
if sample.len() >= size { | ||||
return Ok(self.limit_sample(sample.into_iter().collect(), size)); | ||||
} | ||||
update_sample( | ||||
None, | ||||
headrevs, | ||||
&mut sample, | ||||
Georges Racinet
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r42966 | |r| ParentsIterator::graph_parents(&self.graph, r), | ||
Georges Racinet
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r42965 | Some(size), | ||
)?; | ||||
Ok(sample.into_iter().collect()) | ||||
} | ||||
Georges Racinet
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r42966 | |||
/// Extract a sample from `self.undecided`, going from its heads and roots. | ||||
/// | ||||
/// The `size` parameter is used to avoid useless computations if | ||||
/// it turns out to be bigger than the whole set of undecided Revisions. | ||||
/// | ||||
/// The sample is taken by using `update_sample` from the heads, then | ||||
/// from the roots, working on the reverse DAG, | ||||
/// expressed by `self.children_cache`. | ||||
/// | ||||
/// No effort is being made to complete or limit the sample to `size` | ||||
/// but this method returns another interesting size that it derives | ||||
/// from its knowledge of the structure of the various sets, leaving | ||||
/// to the caller the decision to use it or not. | ||||
fn bidirectional_sample( | ||||
&mut self, | ||||
size: usize, | ||||
) -> Result<(HashSet<Revision>, usize), GraphError> { | ||||
self.ensure_undecided()?; | ||||
{ | ||||
// we don't want to compute children_cache before this | ||||
// but doing it after extracting self.undecided takes a mutable | ||||
// ref to self while a shareable one is still active. | ||||
let undecided = self.undecided.as_ref().unwrap(); | ||||
if undecided.len() <= size { | ||||
return Ok((undecided.clone(), size)); | ||||
} | ||||
} | ||||
self.ensure_children_cache()?; | ||||
let revs = self.undecided.as_ref().unwrap(); | ||||
let mut sample: HashSet<Revision> = revs.clone(); | ||||
// it's possible that leveraging the children cache would be more | ||||
// efficient here | ||||
dagops::retain_heads(&self.graph, &mut sample)?; | ||||
let revsheads = sample.clone(); // was again heads(revs) in python | ||||
// update from heads | ||||
update_sample( | ||||
Some(revs), | ||||
revsheads.iter().cloned(), | ||||
&mut sample, | ||||
|r| ParentsIterator::graph_parents(&self.graph, r), | ||||
None, | ||||
)?; | ||||
// update from roots | ||||
let revroots: HashSet<Revision> = | ||||
dagops::roots(&self.graph, revs)?.into_iter().collect(); | ||||
let prescribed_size = max(size, min(revroots.len(), revsheads.len())); | ||||
let children = self.children_cache.as_ref().unwrap(); | ||||
let empty_vec: Vec<Revision> = Vec::new(); | ||||
update_sample( | ||||
Some(revs), | ||||
revroots, | ||||
&mut sample, | ||||
|r| Ok(children.get(&r).unwrap_or(&empty_vec).iter().cloned()), | ||||
None, | ||||
)?; | ||||
Ok((sample, prescribed_size)) | ||||
} | ||||
/// Fill up sample up to the wished size with random undecided Revisions. | ||||
/// | ||||
/// This is intended to be used as a last resort completion if the | ||||
/// regular sampling algorithm returns too few elements. | ||||
fn random_complete_sample( | ||||
&mut self, | ||||
sample: &mut Vec<Revision>, | ||||
size: usize, | ||||
) { | ||||
let sample_len = sample.len(); | ||||
if size <= sample_len { | ||||
return; | ||||
} | ||||
let take_from: Vec<Revision> = self | ||||
.undecided | ||||
.as_ref() | ||||
.unwrap() | ||||
.iter() | ||||
.filter(|&r| !sample.contains(r)) | ||||
.cloned() | ||||
.collect(); | ||||
sample.extend(self.limit_sample(take_from, size - sample_len)); | ||||
} | ||||
pub fn take_full_sample( | ||||
&mut self, | ||||
size: usize, | ||||
) -> Result<Vec<Revision>, GraphError> { | ||||
let (sample_set, prescribed_size) = self.bidirectional_sample(size)?; | ||||
let size = if self.respect_size { | ||||
size | ||||
} else { | ||||
prescribed_size | ||||
}; | ||||
let mut sample = | ||||
self.limit_sample(sample_set.into_iter().collect(), size); | ||||
self.random_complete_sample(&mut sample, size); | ||||
Ok(sample) | ||||
} | ||||
Georges Racinet
|
r42355 | } | ||
#[cfg(test)] | ||||
mod tests { | ||||
use super::*; | ||||
use crate::testing::SampleGraph; | ||||
/// A PartialDiscovery as for pushing all the heads of `SampleGraph` | ||||
Georges Racinet
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r42965 | /// | ||
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r42968 | /// To avoid actual randomness in these tests, we give it a fixed | ||
/// random seed, but by default we'll test the random version. | ||||
Georges Racinet
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r42355 | fn full_disco() -> PartialDiscovery<SampleGraph> { | ||
Georges Racinet
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r42965 | PartialDiscovery::new_with_seed( | ||
SampleGraph, | ||||
vec![10, 11, 12, 13], | ||||
[0; 16], | ||||
Georges Racinet
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r42966 | true, | ||
Georges Racinet
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r42968 | true, | ||
Georges Racinet
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r42965 | ) | ||
} | ||||
/// A PartialDiscovery as for pushing the 12 head of `SampleGraph` | ||||
/// | ||||
/// To avoid actual randomness in tests, we give it a fixed random seed. | ||||
fn disco12() -> PartialDiscovery<SampleGraph> { | ||||
Georges Racinet
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r42968 | PartialDiscovery::new_with_seed( | ||
SampleGraph, | ||||
vec![12], | ||||
[0; 16], | ||||
true, | ||||
true, | ||||
) | ||||
Georges Racinet
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r42355 | } | ||
fn sorted_undecided( | ||||
disco: &PartialDiscovery<SampleGraph>, | ||||
) -> Vec<Revision> { | ||||
let mut as_vec: Vec<Revision> = | ||||
disco.undecided.as_ref().unwrap().iter().cloned().collect(); | ||||
as_vec.sort(); | ||||
as_vec | ||||
} | ||||
fn sorted_missing(disco: &PartialDiscovery<SampleGraph>) -> Vec<Revision> { | ||||
let mut as_vec: Vec<Revision> = | ||||
disco.missing.iter().cloned().collect(); | ||||
as_vec.sort(); | ||||
as_vec | ||||
} | ||||
fn sorted_common_heads( | ||||
disco: &PartialDiscovery<SampleGraph>, | ||||
) -> Result<Vec<Revision>, GraphError> { | ||||
let mut as_vec: Vec<Revision> = | ||||
disco.common_heads()?.iter().cloned().collect(); | ||||
as_vec.sort(); | ||||
Ok(as_vec) | ||||
} | ||||
#[test] | ||||
fn test_add_common_get_undecided() -> Result<(), GraphError> { | ||||
let mut disco = full_disco(); | ||||
assert_eq!(disco.undecided, None); | ||||
assert!(!disco.has_info()); | ||||
Georges Racinet
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r42357 | assert_eq!(disco.stats().undecided, None); | ||
Georges Racinet
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r42355 | |||
disco.add_common_revisions(vec![11, 12])?; | ||||
assert!(disco.has_info()); | ||||
assert!(!disco.is_complete()); | ||||
assert!(disco.missing.is_empty()); | ||||
// add_common_revisions did not trigger a premature computation | ||||
// of `undecided`, let's check that and ask for them | ||||
assert_eq!(disco.undecided, None); | ||||
disco.ensure_undecided()?; | ||||
assert_eq!(sorted_undecided(&disco), vec![5, 8, 10, 13]); | ||||
Georges Racinet
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r42357 | assert_eq!(disco.stats().undecided, Some(4)); | ||
Georges Racinet
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r42355 | Ok(()) | ||
} | ||||
/// in this test, we pretend that our peer misses exactly (8+10):: | ||||
/// and we're comparing all our repo to it (as in a bare push) | ||||
#[test] | ||||
fn test_discovery() -> Result<(), GraphError> { | ||||
let mut disco = full_disco(); | ||||
disco.add_common_revisions(vec![11, 12])?; | ||||
disco.add_missing_revisions(vec![8, 10])?; | ||||
assert_eq!(sorted_undecided(&disco), vec![5]); | ||||
assert_eq!(sorted_missing(&disco), vec![8, 10, 13]); | ||||
assert!(!disco.is_complete()); | ||||
disco.add_common_revisions(vec![5])?; | ||||
assert_eq!(sorted_undecided(&disco), vec![]); | ||||
assert_eq!(sorted_missing(&disco), vec![8, 10, 13]); | ||||
assert!(disco.is_complete()); | ||||
assert_eq!(sorted_common_heads(&disco)?, vec![5, 11, 12]); | ||||
Ok(()) | ||||
} | ||||
Georges Racinet
|
r42965 | |||
#[test] | ||||
Georges Racinet
|
r42970 | fn test_add_missing_early_continue() -> Result<(), GraphError> { | ||
eprintln!("test_add_missing_early_stop"); | ||||
let mut disco = full_disco(); | ||||
disco.add_common_revisions(vec![13, 3, 4])?; | ||||
disco.ensure_children_cache()?; | ||||
// 12 is grand-child of 6 through 9 | ||||
// passing them in this order maximizes the chances of the | ||||
// early continue to do the wrong thing | ||||
disco.add_missing_revisions(vec![6, 9, 12])?; | ||||
assert_eq!(sorted_undecided(&disco), vec![5, 7, 10, 11]); | ||||
assert_eq!(sorted_missing(&disco), vec![6, 9, 12]); | ||||
assert!(!disco.is_complete()); | ||||
Ok(()) | ||||
} | ||||
#[test] | ||||
Georges Racinet
|
r42965 | fn test_limit_sample_no_need_to() { | ||
let sample = vec![1, 2, 3, 4]; | ||||
assert_eq!(full_disco().limit_sample(sample, 10), vec![1, 2, 3, 4]); | ||||
} | ||||
#[test] | ||||
fn test_limit_sample_less_than_half() { | ||||
assert_eq!(full_disco().limit_sample((1..6).collect(), 2), vec![4, 2]); | ||||
} | ||||
#[test] | ||||
fn test_limit_sample_more_than_half() { | ||||
assert_eq!(full_disco().limit_sample((1..4).collect(), 2), vec![3, 2]); | ||||
} | ||||
#[test] | ||||
Georges Racinet
|
r42968 | fn test_limit_sample_no_random() { | ||
let mut disco = full_disco(); | ||||
disco.randomize = false; | ||||
assert_eq!( | ||||
disco.limit_sample(vec![1, 8, 13, 5, 7, 3], 4), | ||||
vec![1, 3, 5, 7] | ||||
); | ||||
} | ||||
#[test] | ||||
Georges Racinet
|
r42965 | fn test_quick_sample_enough_undecided_heads() -> Result<(), GraphError> { | ||
let mut disco = full_disco(); | ||||
disco.undecided = Some((1..=13).collect()); | ||||
let mut sample_vec = disco.take_quick_sample(vec![], 4)?; | ||||
sample_vec.sort(); | ||||
assert_eq!(sample_vec, vec![10, 11, 12, 13]); | ||||
Ok(()) | ||||
} | ||||
#[test] | ||||
fn test_quick_sample_climbing_from_12() -> Result<(), GraphError> { | ||||
let mut disco = disco12(); | ||||
disco.ensure_undecided()?; | ||||
let mut sample_vec = disco.take_quick_sample(vec![12], 4)?; | ||||
sample_vec.sort(); | ||||
// r12's only parent is r9, whose unique grand-parent through the | ||||
// diamond shape is r4. This ends there because the distance from r4 | ||||
// to the root is only 3. | ||||
assert_eq!(sample_vec, vec![4, 9, 12]); | ||||
Ok(()) | ||||
} | ||||
Georges Racinet
|
r42966 | |||
#[test] | ||||
fn test_children_cache() -> Result<(), GraphError> { | ||||
let mut disco = full_disco(); | ||||
disco.ensure_children_cache()?; | ||||
let cache = disco.children_cache.unwrap(); | ||||
assert_eq!(cache.get(&2).cloned(), Some(vec![4])); | ||||
assert_eq!(cache.get(&10).cloned(), None); | ||||
let mut children_4 = cache.get(&4).cloned().unwrap(); | ||||
children_4.sort(); | ||||
assert_eq!(children_4, vec![5, 6, 7]); | ||||
let mut children_7 = cache.get(&7).cloned().unwrap(); | ||||
children_7.sort(); | ||||
assert_eq!(children_7, vec![9, 11]); | ||||
Ok(()) | ||||
} | ||||
#[test] | ||||
fn test_complete_sample() { | ||||
let mut disco = full_disco(); | ||||
let undecided: HashSet<Revision> = | ||||
[4, 7, 9, 2, 3].iter().cloned().collect(); | ||||
disco.undecided = Some(undecided); | ||||
let mut sample = vec![0]; | ||||
disco.random_complete_sample(&mut sample, 3); | ||||
assert_eq!(sample.len(), 3); | ||||
let mut sample = vec![2, 4, 7]; | ||||
disco.random_complete_sample(&mut sample, 1); | ||||
assert_eq!(sample.len(), 3); | ||||
} | ||||
#[test] | ||||
fn test_bidirectional_sample() -> Result<(), GraphError> { | ||||
let mut disco = full_disco(); | ||||
disco.undecided = Some((0..=13).into_iter().collect()); | ||||
let (sample_set, size) = disco.bidirectional_sample(7)?; | ||||
assert_eq!(size, 7); | ||||
let mut sample: Vec<Revision> = sample_set.into_iter().collect(); | ||||
sample.sort(); | ||||
// our DAG is a bit too small for the results to be really interesting | ||||
// at least it shows that | ||||
// - we went both ways | ||||
// - we didn't take all Revisions (6 is not in the sample) | ||||
assert_eq!(sample, vec![0, 1, 2, 3, 4, 5, 7, 8, 9, 10, 11, 12, 13]); | ||||
Ok(()) | ||||
} | ||||
Georges Racinet
|
r42355 | } | ||